Extracellular vesicles derived from M1 macrophages deliver MPPED2 and regulate PI3K/AKT to suppress trophoblast autophagy and proliferation in recurrent spontaneous abortion

Abstract Background Increasing evidence suggests that the biological activity of trophoblasts and M1-type macrophages plays a crucial role in recurrent spontaneous abortion. However, detailed mechanistic studies on the intercellular communication between these two cells at the maternal-fetal interface are not clear. Methods In this study, extracellular vesicles (EVs) were first isolated from the supernatant of M1 macrophages induced by THP-1 cells (M1-EVs), identified by transmission electron microscopy, exosome immunofluorescence uptake, and western blotting, and characterized by mRNA sequencing to screen for specific target genes by mRNA profiling. CCK8 and western blotting experiments were used to investigate the effects of M1-EVs on trophoblast proliferation and autophagy. Subsequently, target genes MPPED2 and PI3K/AKT signaling pathway were found by bioinformatics analysis of raw mRNA sequencing results. Western blotting and CCK8 experiments were used to reveal the potential mechanisms by which MPPED2 in M1-EVs regulates trophoblast function. Results M1 macrophages induce inflammatory responses in the mother and fetus, and M1 macrophages inhibit trophoblast autophagy and proliferative capacity by secreting EVs. By mRNA transcriptome sequencing, MPPED2, among others, were identified as the most up-regulated mRNAs in M1-EVs-treated trophoblasts. Further functional experiments indicate that M1 macrophage-derived exosomes may regulate PI3K/AKT pathway activity by transferring MPPED2, leading to reduced autophagy and proliferation activity in trophoblasts. Conclusion Our findings suggest that MPPED2 from exosomes plays an important role in intercellular communication between M1 macrophages and the trophoblast, elucidating a novel mechanism by which M1 macrophages regulate trophoblast function and its role in recurrent spontaneous abortion.